A method and apparatus for autonomous, automatic interleaving of cycled loads coupled to a grid. In one or more embodiments, the method comprises (i) determining, by a smart load coupled to a grid, a first grid stress value; (ii) comparing, by the smart load, the first grid stress value to an activation threshold; (iii) waiting, by the smart load, when the first grid stress value is less than the activation threshold, a delay period; (iv) determining, by the smart load and after the delay period ends, a second grid stress value; (v) comparing, by the smart load, the second grid stress value to the activation threshold; and (iv) activating, by the smart load, when the second grid stress value is less than the activation threshold.

An energy management system interoperates with an automation system to provide integrated control over essentially all power-consuming, power-generating, and power storage devices in a home or other environment. The energy management system provides configurable energy management scenes in which one or more values, each representing a desired operating condition, are associated with some or all of the loads of a home, business or other environment. Different energy management scenes may be configured for different environmental conditions including season, day of week, time of day, grid status, battery condition, and generator condition among others.

The present teaching provides a power supply system capable of appropriately performing replacement or repairing of a component of a module where a problem occurs without stopping the entire operation, in a case where the problem occurs in of the module in a plurality of modules. The power supply system includes a plurality of sweep modules, a problem detector, an indicator, and a controller. Each sweep module includes a battery module and an electric power circuit module. The problem detector detects a problem for each sweep module. The indicator indicates a sweep module in which a problem is detected. In a case where a problem is detected in the sweep module (S4: YES), the controller causes the indicator to indicate a failure sweep module in which the problem is detected (S5). The controller disconnects the failure sweep module from a main line, and continues sweep control (S6 through S8).

The present system relates to a power topology mapping system for identifying which one of one or more equipment components are being powered from a specific phase of a multi-phase AC power source. The system makes use of a plurality of power receiving subsystems which each receive an AC power signal from at least one phase of the multi-phase AC power source. Each power receiving subsystem has a communications card, an identification designation unique to it, and a controller. One of the power receiving subsystems is designated as a reference power domain component. The controllers each carry out phase angle measurements associated with the AC power signal being received by its power receiving subsystem. A topology mapping subsystem is included which analyzes phase angle measurement data reported by the power receiving subsystems and determines which subsystem is being powered by which phase of the multi-phase AC signal.

A system and method for combining a remote audio source with an animatronically controlled puppet includes the steps of entering an audio file on a user client by a person where the audio file is a statement spoken by the person. The audio file is sent to a secondary client that is remote to the user client. The secondary client has a puppet controlled by animatronics. The audio file is received by an audio circuit board that converts the audio file into movement parameters. The movement parameters are sent to at least one servomechanism mounted in the puppet to actuate the animatronics in synchronicity with the audio file. Movement of the puppet is video recorded to define a video file. The audio and video files are combined to define a final video production viewable by the person.

Disclosed is a power management system implemented on a user device, for at least one power utilizing entity, the power management system comprising: a transfer switch, wherein the transfer switch is configured to: provide power to the at least one power utilizing entity via distribution lines; or provide power to the at least one power utilizing entity via a generator upon failure of distribution lines; a phase switch, wherein the phase switch is configured to: provide power to the at least one power utilizing entity via one or more power sources upon failure of the distribution lines and the generator; and a user device, wherein the user device is configured to enable: the transfer switch to switch between power provided via distribution lines and generator; and the phase switch to switch between power provided via one or more power sources.

A distributed low voltage power system can include a power distribution module (PDM) that distributes a low voltage signal through at least one output channel. The system can also include at least one electrical device coupled to the at least one output channel of the PDM, where the at least one electrical device operates using the low voltage signal. The system can further include an emergency battery pack (EBP) coupled to the at least one output channel of the PDM and to the at least one electrical device, where the EBP comprises at least one battery cell. The EBP can use the low voltage signal to charge the at least one battery cell, and where the EBP releases emergency low voltage signal to the at least one electrical device when the PDM stops distributing the low voltage signal.

An uninterruptible power supply (UPS) is operated to selectively provide energy to a critical load from a grid and an energy storage device and to transfer energy between the energy storage device and the grid. A controller causes the UPS to selectively support bidirectional and unidirectional transfers of energy between the grid and the energy storage device based on a state of charge (SOC) of the energy storage device.

A system to manage power consumption from a grid includes a building switchgear; an independent system organization (ISO) meter coupled to the building switchgear, the ISO meter including a telemetry unit to communicate with an ISO; and an energy storage system (ESS) coupled to the building switchgear, wherein the ESS selectively provides power in response to a customer power demand to prevent a customer grid power consumption from spiking and peaking at grid imbalance highest cost on peak times.

Example implementations relate to power delivery monitor and control with an uninterruptible power supply (UPS). For example, a UPS includes a power output receptacle to supply power to a power extension bar coupled to the UPS via a power cable, the extension bar to provide the power to a plurality of computing devices coupled to the extension bar. The UPS also includes a data communication port to couple the UPS to the extension bar via a communication cable, and a controller module to monitor and control power delivered to a plurality of power output receptacles on the extension bar.